Sheet feeding apparatus and image forming apparatus

ABSTRACT

A sheet feeding apparatus includes a sheet supporting portion to support a sheet, a feeding member to contact an upper surface of the sheet supported on the sheet supporting portion and feed the sheet, and a drive motor to rotate in a first direction and in a second direction opposite to the first direction. In addition, a lifting mechanism is connected to the drive motor to lift the sheet supporting portion and lower the feeding member in a case where the drive motor rotates in the first direction, and to lower the sheet supporting portion and lift the feeding member in a case where the drive motor rotates in the second direction.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a sheet feeding apparatus for feedingsheets and an image forming apparatus for forming an image on a sheet.

Description of the Related Art

Image forming apparatuses such as printers, copying machines andmultifunctional devices include a sheet feeding apparatus that feedssheets serving as recording materials or original documents one at atime from a pile of sheets stacked on a tray using a feeding member suchas a feed roller or a pickup roller for feeding sheets. In such a sheetfeeding apparatus, if the feed roller is in contact with the sheet for along time, the oil contained in a rubber material forming an outercircumferential portion of the roller may ooze out onto the sheet, whichmay cause image defects in the subsequent printing operation.

Japanese Patent Application Laid-Open Publication No. 2018-24513discloses a document feeding apparatus including a pickup roller thatsends out paper while a motor rotates in a normal direction and thepickup roller is separated from the paper while the motor rotates in areverse direction. According to a sheet feeding apparatus disclosed inJapanese Patent Application Laid-Open Publication No. 2010-64805, when asheet feed cassette is attached to an apparatus body, a motor rotates ina normal direction to have a sheet bundle placed on a lift plate contacta pickup roller, and when the sheet feeding operation is ended, themotor rotates in a reverse direction to separate the sheet bundle fromthe pickup roller.

In the configurations disclosed in the above documents, it was necessaryto rotate the motor in the reverse direction with sufficient driveamount to separate the pickup roller from the paper. However, variousdrawbacks occur as the time for driving the motor in the reversedirection extends, such as the elongation of period of generation ofoperation noise or reduction of life of the motor.

SUMMARY OF THE INVENTION

The present invention provides a sheet feeding apparatus and an imageforming apparatus that can shorten a time required for separating afeeding member from a sheet.

According to one aspect of the invention, a sheet feeding apparatusincludes a sheet supporting portion configured to support a sheet, afeeding member configured to contact an upper surface of the sheetsupported on the sheet supporting portion and feed the sheet, a drivemotor configured to rotate in a first direction and in a seconddirection opposite to the first direction, and a lifting mechanismconnected to the drive motor and configured to lift the sheet supportingportion and lower the feeding member in a case where the drive motorrotates in the first direction, and to lower the sheet supportingportion and lift the feeding member in a case where the drive motorrotates in the second direction.

Further features of the present invention will become apparent from thefollowing description of exemplary embodiments with reference to theattached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic drawing of an image forming apparatus according toa first embodiment.

FIG. 2 is a cross-sectional view of a sheet feed unit according to thefirst embodiment.

FIG. 3A is a perspective view illustrating a lift plate and a liftingmechanism thereof according to the first embodiment.

FIG. 3B is a perspective view illustrating the lift plate and thelifting mechanism thereof according to the first embodiment.

FIG. 4 is a perspective view illustrating a lifting mechanism of a feedroller according to the first embodiment.

FIG. 5A is a view illustrating a lifting and lowering operation of thefeed roller and the lift plate according to the first embodiment.

FIG. 5B is a view illustrating the lifting and lowering operation of thefeed roller and the lift plate according to the first embodiment.

FIG. 6A is a view illustrating the lifting and lowering operation of thefeed roller and the lift plate according to the first embodiment.

FIG. 6B is a view illustrating the lifting and lowering operation of thefeed roller and the lift plate according to the first embodiment.

FIG. 7A is an explanatory view illustrating the lifting and loweringoperation of the feed roller and the lift plate according to the firstembodiment.

FIG. 7B is an explanatory view illustrating the lifting and loweringoperation of the feed roller and the lift plate according to the firstembodiment.

FIG. 7C is an explanatory view illustrating the lifting and loweringoperation of the feed roller and the lift plate according to the firstembodiment.

FIG. 7D is an explanatory view illustrating the lifting and loweringoperation of the feed roller and the lift plate according to the firstembodiment.

FIG. 8 is a block diagram illustrating a control configuration of theimage forming apparatus according to the first embodiment.

FIG. 9 is a flowchart illustrating a control method of the image formingapparatus according to the first embodiment.

FIG. 10 is a perspective view illustrating a lifting mechanism of a feedroller according to a second embodiment.

FIG. 11A is a view illustrating a lifting and lowering operation of thefeed roller and a lift plate according to the second embodiment.

FIG. 11B is a view illustrating the lifting and lowering operation ofthe feed roller and the lift plate according to the second embodiment.

FIG. 12A is a view illustrating the lifting and lowering operation ofthe feed roller and the lift plate according to the second embodiment.

FIG. 12B is a view illustrating the lifting and lowering operation ofthe feed roller and the lift plate according to the second embodiment.

DESCRIPTION OF THE EMBODIMENTS

Now, exemplary embodiments of the present invention will be described indetail with reference to the drawings.

First Embodiment

FIG. 1 is a schematic drawing illustrating an image forming apparatus 1according to a first embodiment. The image forming apparatus 1 is alaser beam printer adopting an electrophotographic system that formsmonochromatic toner images. The image forming apparatus 1 includes asheet feeder 2 for feeding sheets serving as recording materials, and animage forming unit 5 that forms images on sheets. Recording materialscan be plain paper, thick paper, plastic films, cloth, sheet materialssubjected to surface treatment such as coated paper, special-shapedsheet material such as envelopes and index paper, and various othersheets having different sizes and materials.

The image forming unit 5 includes a processing cartridge P, a laserscanner 52 and a transfer roller 53. When an image forming command isentered to the image forming apparatus 1, the image forming unit 5starts an image forming operation by an electrophotographic process.That is, a photosensitive drum 51 provided in the processing cartridge Pstarts to rotate, and a charging unit charges a surface of the drumuniformly. The laser scanner 52 irradiates the photosensitive drum 51with a laser beam and exposes the photosensitive drum 51 based on imageinformation entered to the image forming apparatus 1, to draw anelectrostatic latent image on the drum surface. The latent image isdeveloped using developer supplied from a developer container to form atoner image on the photosensitive drum 51.

In parallel with this process, a sheet S is fed from the sheet feeder 2.The sheet feeder 2 includes a feed roller 211 that feeds the sheet Ssupported on a lift plate 31 of a cassette 3 that can be drawn out of acasing of the image forming apparatus 1. The sheet S fed by the sheetfeeder 2 is conveyed via a conveyance roller pair 4 to a transferportion which is a nip portion between the photosensitive drum 51 andthe transfer roller 53. In the transfer portion, a bias voltage havingan opposite polarity as normal charge polarity of toner is applied tothe transfer roller 53, by which the toner image borne on thephotosensitive drum 51 is transferred to the sheet S.

A fixing unit 6 forms a fixing nip by a heating unit 61, which iscomposed of a fixing film and a ceramic heater serving as a heatingelement arranged on an inner circumferential side of the fixing film,and a pressure roller 62 in pressure contact with the heating unit 61.While the sheet S passes through the fixing nip, the toner image on thesheet is heated and pressed, by which toner is melted and fixed to havethe unfixed image permanently fixed to the sheet S. The sheet S havingpassed through the fixing unit 6 is discharged via a sheet dischargepath 7 to an exterior of the device by a sheet discharge roller pair 8and stacked on a sheet discharge tray 9.

The present embodiment uses the image forming unit 5 serving as a directtransfer-type electrophotographic unit as the image forming unit forforming images on sheets. However, an intermediate transfer-typeelectrophotographic unit for transferring a toner image formed on aphotosensitive member via an intermediate transfer body such as anintermediate transfer belt to a sheet can also be used as the imageforming unit. Further, an inkjet-type image forming unit for forming animage on a sheet by discharging ink through nozzles can also be used asthe image forming unit, for example.

Sheet Feeder

A detailed configuration of the sheet feeder 2 serving as a sheetfeeding apparatus according to the present embodiment will be describedwith reference to FIG. 2 . FIG. 2 is a cross-sectional view of the sheetfeeder 2 viewed in a width direction, that is, a direction orthogonal toa feeding direction, of the sheet fed by the sheet feeder 2.

The sheet feeder 2 includes a feeding frame 22, a feed roller unit 21and a separation roller 24. The feeding frame 22 is fixed to a framemember of the image forming apparatus and constitutes a frame member ofthe sheet feeding apparatus according to the present embodiment. Thefeed roller unit 21 and the separation roller 24 are supported on thefeeding frame 22. The cassette 3 is a sheet storage portion of thepresent embodiment for storing sheets and can be opened and closed withrespect to a body of the image forming apparatus, in other words, can bemoved with respect to the feeding frame 22, wherein opening and closingof the cassette is configured to be detected by a cassette open/closesensor 74 (FIG. 8 ).

The feed roller unit 21 is a unit including the feed roller 211, aconveyance roller 212, a roller holder 213 and an idler gear 214. Thefeed roller 211 and the conveyance roller 212 are held rotatably by theroller holder 213 serving as a retaining member. The roller holder 213is capable of swinging about a rotational axis of the conveyance roller212. A pressurization mechanism such as a spring member is connected toroller holder 213 to urge the feed roller 211 downward so as to applypressurization force to the feed roller 211 against the sheet.

The feed roller 211 serving as a feeding member is driven by a sheetfeed motor serving as a driving source described later to rotate in acounterclockwise direction in FIG. 2 , and feeds the sheet supported onthe lift plate 31 serving as a sheet supporting portion toward thefeeding direction, corresponding to the right side of FIG. 2 . Theconveyance roller 212 is also driven by the sheet feed motor whichserves as a common driving source, to rotate in the counterclockwisedirection in FIG. 2 and further convey the sheet downstream in thefeeding direction.

The separation roller 24 serving as a separation member is a rollermember connected via a torque limiter to a shaft fixed to the feedingframe 22. The separation roller 24 contacts the conveyance roller 212and forms a separation nip therewith, separating the sheet passingthrough the separation nip by frictional force. That is, if only onesheet sent out by the feed roller 211 passes through the separation nip,the torque limiter slips so that the separation roller 24 corotates withthe conveyance roller 212 via the sheet. Meanwhile, if multiple sheetsenter the separation nip, the separation roller 24 stops rotating sothat the sheets are slid against one another, and only the uppermostsheet in contact with the conveyance roller 212 is conveyed. Such aseparation roller 24 is an example of a separation member, and othermembers, such as a retard roller to which driving force in an oppositedirection to the sheet feeding direction, i.e., counterclockwisedirection in FIG. 2 , is entered from a sheet feed motor, or apad-shaped friction member in contact with the conveyance roller 212,can be used.

A feed position sensor 215, whose detection signal changes according towhether an upper surface of the sheet (i.e., upper surface of theuppermost sheet) placed on the lift plate 31 is at an appropriate heightfor feeding sheets by the feed roller 211, is provided on the sheetfeeder 2. The appropriate height is hereinafter referred to as feedingposition. The feed position sensor 215 is a detection member fordetecting the position of the roller holder 213, and in the presentembodiment, a photo-interrupter to be shielded of light by a detectionportion 213 a, serving as a light shielding portion, provided on theroller holder 213 is used. If the detection portion 213 a is positionedon an optical axis of the feed position sensor 215, it is determinedthat the upper surface of the sheet supported on the lift plate 31 ispositioned at the feeding position, and if not, it is determined thatthe upper surface of the sheet is positioned either above or below thefeeding position.

As described, in a case where the sheet feeder 2 starts a sheet feedingoperation, the feed roller 211 lowers from an upper position positionedabove the feeding position and moves temporarily to a lower positionpositioned below the feeding position. In this state, when the uppersurface of the sheet contacts the feed roller 211 by the lift plate 31being lifted, the roller holder 213 is lifted against the urging forceof the pressurization mechanism. Then, when the feed position sensor 215detects the detection portion 213 a, lifting of the lift plate 31 isstopped. If the lift plate 31 is lifted in a state where no sheets areplaced on the lift plate 31, the lift plate itself will be in contactwith the feed roller 211.

In a state where the feed roller 211 is in contact with the sheet at thefeeding position, the sheet feed motor rotates the feed roller 211 andthe conveyance roller 212, by which the sheets are sent out from thecassette 3. Then, the sheets are separated one sheet at a time by theconveyance roller 212 and the separation roller 24 and conveyed to theconveyance roller pair 4. By repeating the feeding of sheets, the numberof sheets stacked on the lift plate 31 will reduce, and along therewith,the position of the feed roller 211 is gradually lowered. If thedetection portion 213 a of the roller holder 213 moves to a positionwhere it cannot be detected by the feed position sensor 215, a liftmotor 35 lifts the lift plate 31 again until the feed position sensor215 detects the detection portion 213 a. Thereby, the upper surface ofthe sheets stacked on the lift plate 31 will constantly be controlled tofall within a fixed range.

Lifting and Lowering of Lift Plate

Next, a lifting mechanism provided on the cassette 3 will be describedwith reference to FIGS. 3A and 3B. FIGS. 3A and 3B are perspective viewsillustrating a general configuration of a lifting mechanism 30 accordingto the present embodiment. FIG. 3A illustrates an initial state wherethe lift plate 31 is at an initial position, and FIG. 3B illustrates alift-up state where the lift plate 31 is positioned upward of theinitial position.

As illustrated in FIG. 3A, the lifting mechanism 30 includes a liftmember 32, a lift input gear 34 and a lift output gear 33. The liftmember 32 is arranged between a bottom portion of the cassette 3 and thelift plate 31, supported pivotably by the cassette 3 and lifts or lowersthe lift plate 31 by pivoting. The lift output gear 33 is a sector gearthat pivots integrally with the lift member 32 and that is meshed withthe lift input gear 34. The lift input gear 34 is coupled to a liftmotor 35 serving as a driving source via a reduction gear train 38 androtates by driving force of the lift motor 35.

In the lifting mechanism 30, the reduction gear train 38 constitutes atransmission portion that also transmits the driving force of the liftmotor 35 to a roller lifting portion 30B described later. The liftoutput gear 33, the lift input gear 34 and the lift member 32 operate byreceiving the driving force from the transmission portion, and theyconstitute a lift plate lifting portion 30A, serving as a first liftingportion according to the present embodiment, for lifting the lift plate31.

The lift motor 35 is a drive motor that rotates in a first direction andin a second direction opposite to the first direction based on a commandsignal from a control unit 70 described later. Hereafter, the directionof rotation of the lift motor 35 for lifting the lift member 32 to liftthe lift plate 31 up, that is, first direction in the presentembodiment, is referred to as a “normal direction”. In contrast, thedirection of rotation of the lift motor 35 for lowering the lift member32 and lowering the lift plate 31, that is, second direction in thepresent embodiment, is referred to as a “reverse direction”.

The lift member 32 and the lift output gear 33 are supported on thecassette 3, and the lift input gear 34 and the reduction gear train 38are supported on the frame member of the image forming apparatustogether with the lift motor 35. Therefore, if the cassette 3 is drawnout in a width direction W, that is, a direction perpendicular to afeeding direction Fd, of the sheet in FIGS. 3A and 3B, meshing of thelift output gear 33 and the lift input gear 34 is disengaged. If thecassette 3 is inserted to a predetermined attachment positionillustrated in FIGS. 3A and 3B with respect to the image formingapparatus, the lift output gear 33 and the lift input gear 34 aremeshed, and the lift member 32 will be in a state constantly coupled tothe lift motor 35. Therefore, according to the present embodiment, in astate where the cassette 3 is closed, the lift motor 35 is capable ofboth lifting and lowering the lift plate 31.

The reduction gear train 38 includes a worm gear 38 a and a plurality ofstep gears 38 b and 38 c (refer also to FIG. 4 ), and the reduction geartrain 38 decelerates rotation of the lift motor 35 and transmits therotation to a large-diameter gear 38 d formed integrally with the liftinput gear 34. Therefore, even if a small motor having a relativelysmall output torque is used as the lift motor 35, lifting and loweringoperation of the lift plate 31, and also that of the feed roller 211described later, can be performed stably.

Lifting Mechanism of Feed Roller

Next, the roller lifting portion 30B, serving as a second liftingportion according to the present embodiment, which is a mechanism forlifting and lowering the feed roller 211 using the driving force of thelift motor 35 will be described with reference to FIG. 4 . The rollerlifting portion 30B is provided between the lift motor 35 and the feedroller unit 21 in a manner coupling the reduction gear train 38 servingas a transmission portion and the roller holder 213. The roller liftingportion 30B is an apparatus, i.e., feed roller contact-separationportion, that uses the driving force of the lift motor 35 to swing theroller holder 213 to thereby cause the feed roller 211 to contact orseparate from the sheet.

The roller lifting portion 30B is composed of a roller lifting gear 36,a roller lifting link 37 and a roller lifting lever 25. The rollerlifting gear 36 is coupled to the lift motor 35 via the reduction geartrain 38. The roller lifting lever 25 is a swing member that is coupledto the feed roller unit 21 and that swings in linkage with the feedroller unit 21. The roller lifting link 37 is a link member thatincludes a rack portion 37 a meshed with the roller lifting gear 36 andthat couples the roller lifting gear 36 with the roller lifting lever25.

The roller lifting link 37 and the roller lifting lever 25 are supportedmovably by the feeding frame 22. The roller lifting link 37 is capableof moving in sliding motion upward and downward, that is, approximatelyin the vertical direction (i.e., the gravity direction), and convertingthe rotation of the roller lifting gear 36 meshed with the rack portion37 a to linear motion in the upward and downward directions. The rollerlifting link 37 is lowered by rotation of the lift motor 35 in thenormal direction, and the roller lifting link 37 is lifted by therotation of the lift motor 35 in the reverse direction.

The roller lifting lever 25 is a swing member capable of swinging up anddown about a swing axis X1 that extends in a rotational axis direction,that is, sheet width direction, of the feed roller 211. The rollerlifting lever 25 is engaged with the roller holder 213 of the feedroller unit 21 at one end portion 25 a in the axial direction and swingsup and down with the roller holder 213. The other end portion 25 b inthe axial direction of the roller lifting lever 25 opposes to a pressingportion 37 b provided on an upper end of the roller lifting link 37. Anengagement portion between the pressing portion 37 b and the end portion25 b of the roller lifting lever 25 is configured to allow, when thefeed roller 211 is pressed by the sheet, the roller holder 213 and theroller lifting lever 25 to swing upward in a state where the rollerlifting link 37 is stopped. Further, a pressurizing spring 39 serving asan urging member is attached between the roller lifting lever 25 and thefeeding frame 22, by which the roller lifting lever 25 is urgeddownward. In FIG. 4 , the pressurizing spring 39 is illustrated as atorsion coil spring, but the configuration of the urging member is notlimited thereto, and for example, a torsion coil spring mounted aroundthe swing axis X1 may also be used.

In a case where the roller lifting link 37 is lowered by rotation of thelift motor 35 in the normal direction, the roller lifting lever 25pivots downward by an action of urging force of the pressurizing spring39 and the own weight of the roller lifting lever 25. In a case wherethe roller lifting link 37 is lifted by rotation of the lift motor 35 inthe reverse direction, the roller lifting lever 25 is pressed by thepressing portion 37 b of the roller lifting link 37 and swings upward.

Further, the feed roller unit 21 is detachably attached to the feedingframe 22, and an engagement position, i.e., connecting portion, of thefeed roller unit 21 and the roller lifting lever 25 is also detachable.The engagement position is configured so that the end portion 25 a ofthe roller lifting lever 25 is fitted to a hook portion 213 b providedon the roller holder 213.

The feed roller unit 21 can be removed from the feeding frame 22 towarda predetermined removing direction R that intersects the rotational axisof the feed roller 211, in other words, a direction that intersects theaxial direction of the swing axis X1 of the roller lifting lever 25. Incorrespondence therewith, the hook portion 213 b is formed in a recessedshape with the upstream side in the removing direction R recessed, andalong with a removal operation of removing the feed roller unit 21, theend portion 25 a of the roller lifting lever 25 is disengaged from thehook portion 213 b. In a case where the feed roller unit 21 is attachedto the feeding frame 22 toward a direction opposite to the removingdirection R, the end portion 25 a of the roller lifting lever 25 fits tothe hook portion 213 b, and the roller lifting lever 25 will be in astate swinging together with the roller holder 213.

As described later, drive amount of the lift motor 35 for driving thelift plate 31 in the operation of moving the feed roller 211 to be incontact with and separated from the sheet is normally greater than thedrive amount of the lift motor 35 for lifting and lowering the feedroller 211. A torque limiter is assembled to the roller lifting gear 36,for example, as a mechanism for absorbing such difference of driveamount by shutting off drive transmission to the roller lifting lever 25in the roller lifting portion 30B. Further, stoppers 49 a and 49 b forregulating range of movement of the roller lifting link 37 is fixed tothe feeding frame 22 in the roller lifting portion 30B. The shape of thestopper 49 a is not necessarily the illustrated shape, i.e., blockshape, and for example, a hole capable of receiving a protruded shapeformed on the roller lifting link 37 can be provided on a metal plateconstituting the feeding frame as the stopper.

In a case where the lift motor 35 rotates in the normal direction, whenthe roller lifting link 37 is lowered to a position in contact with thestopper 49 a, the torque limiter slips so that the roller lifting link37 is not lowered further. The position of the roller lifting link 37 inthis state corresponds to the lower limit of the lifting and loweringrange of the feed roller 211. The lift motor 35 continues to rotate inthe normal direction in a state where the roller lifting link 37 is incontact with the stopper 49 a, by which the lift plate 31 is continuedto be lifted. Similarly, in a case where the lift motor 35 rotates inthe reverse direction, when the roller lifting link 37 is lifted to aposition in contact with the stopper 49 b, the torque limiter slips sothat the roller lifting link 37 is not lifted further. The position ofthe roller lifting link 37 in this state corresponds to the upper limitof the lifting and lowering range of the feed roller 211. The lift motor35 continues to rotate in the reverse direction in a state where theroller lifting link 37 is in contact with the stopper 49 b, by which thelift plate 31 is continued to be lowered. In other words, the torquevalue of the torque limiter of the roller lifting gear 36 is set to avalue high enough to swing the roller lifting lever 25 together with theroller holder 213 but low enough so that the roller lifting link 37 isstopped by the stoppers 49 a and 49 b.

An example has been illustrated of a case where a torque limiter ispositioned between the lift motor 35 and the roller lifting link 37, butinstead, a one-way gear may be arranged between the lift motor 35 andthe roller lifting link 37. In that case, in a state where the liftmotor 35 is stopped, the one-way gear is designed to be locked when theroller lifting link 37 is lowered and rotates idly when the rollerlifting link 37 is lifted. In this case, if the lift motor 35 rotates inthe reverse direction, the roller lifting link 37 is lifted in a statewhere the one-way gear is locked, and the feed roller 211 is therebylifted. Meanwhile, if the lift motor 35 rotates in the normal direction,the roller lifting link 37 is allowed to be lowered by the action of theurging force of the pressurizing spring 39. When the roller lifting link37 is lowered to the lower limit position, the lowering of the rollerlifting link 37 is stopped and the one-way gear rotates idly. Asdescribed, in lifting the feed roller 211, the roller lifting link 37 ismoved in a movement direction, i.e., upward in the present embodiment,for lifting the feed roller 211 by drive transmission via the one-waygear in the locked state, so that the feed roller 211 can be lifted morereliably. Meanwhile, in lowering the feed roller 211, the roller liftinglink 37 moves in a movement direction, i.e., downward in the presentembodiment, for lowering the feed roller 211 by the urging force of thepressurizing spring 39, so that the feed roller 211 can be in contactwith the sheet with appropriate pressurizing force by adjusting thespring force of the pressurizing spring 39.

Operation of Lifting Mechanism

Next, a lifting and lowering operation of the lift plate 31 and the feedroller 211 by the lifting mechanism 30 according to the presentembodiment will be described with reference to FIGS. 5A to 7D. FIG. 5Ais a schematic drawing illustrating a state where the feed roller 211 isin contact with the sheet on the lift plate 31, hereinafter referred toas a feed-roller contact state, viewed in the rotational axis direction,i.e., sheet width direction, of the feed roller 211. FIG. 5B is aschematic drawing illustrating a state where the feed roller 211 isseparated from the sheet on the lift plate 31, hereinafter referred toas a feed-roller separated state, viewed in the rotational axisdirection of the feed roller 211. FIG. 6A is a schematic drawingillustrating the feed-roller contact state viewed from the downstreamside of the feeding direction, and FIG. 6B is a schematic drawingillustrating the feed-roller separated state viewed from the downstreamside of the feeding direction.

As illustrated in FIGS. 5A and 6A, the lift motor 35 rotates in thenormal direction in an operation of transiting from the feed-rollerseparated state to the feed-roller contact state, that is, in afeed-roller contact operation. Thereby, the lifting mechanism 30performs operation to lower the feed roller 211 by the roller liftingportion 30B and lift the lift plate 31 by the lift plate lifting portion30A. That is, by the lift motor 35 rotating in the normal direction, theroller lifting link 37 is lowered (arrow A1), along with which theroller lifting lever 25 pivots downward (arrow B1), and the feed rollerunit 21 pivots downward in linkage with the roller lifting lever 25(arrow C1). In parallel therewith, the lift member 32 pivots upward bythe lift motor 35 rotating in the normal direction, and the lift plate31 is thereby lifted (arrow D1). As described earlier, in a case wherethe feed position sensor 215 detects the detection portion 213 a of theroller holder 213, the lifting of the lift plate 31 is stopped and thefeed-roller contact state is realized.

Meanwhile, as illustrated in FIGS. 5B and 6B, the lift motor 35 rotatesin the reverse direction in an operation of transiting from thefeed-roller contact state to the feed-roller separated state, that is,in a feed-roller separating operation. Thereby, the lifting mechanism 30performs operation to lift the feed roller 211 by the roller liftingportion 30B and lower the lift plate 31 by the lift plate liftingportion 30A. That is, by the lift motor 35 rotating in the reversedirection, the roller lifting link 37 is lifted (arrow A2), along withwhich the roller lifting lever 25 pivots upward (arrow B2), and the feedroller unit 21 pivots upward in linkage with the roller lifting lever 25(arrow C2). In parallel therewith, the lift member 32 pivots downward bythe rotation of the lift motor 35 in the reverse direction and lowersthe lifting plate 31 (arrow D2). Thereby, the feed-roller separatedstate is realized.

FIGS. 7A to 7D illustrate the process of the feed-roller separatingoperation in a simplified manner. FIG. 7A illustrates a feed-rollercontact state, FIG. 7B illustrates a state in midway of separationoperation, and FIG. 7C illustrates a state where the separationoperation has been completed. FIG. 7D illustrates a state where only thelift plate 31 is lowered from the feed-roller contact state to theinitial position, as a reference drawing. The dotted line tin FIGS. 7Ato 7D illustrate an appropriate height position, that is, feedingposition, in which the feed roller 211 comes into contact with the uppersurface of the sheet for feeding sheets.

As described earlier, according to the present embodiment, the feedroller 211 is lifted and lowered using the driving force of the liftmotor 35, and in the feed-roller separating operation, the lifting ofthe feed roller 211 (arrow C2) and the lowering of the lift plate 31(arrow D2) proceed simultaneously, as illustrated in FIG. 7B. Thereby,the feed-roller separating operation is completed speedily.

Now, the feed roller unit 21 is urged downward by the urging force ofthe pressurizing spring 39, and the feeding position (t) is set to beabove the lower position serving as a lower limit of the movable rangeof the feed roller 211 to ensure an appropriate pressurizing force tothe sheet. That is, during the feed-roller contact state, the rollerlifting link 37 is at a position corresponding to the lower position ofthe feed roller 211, while the feed roller unit 21 and the rollerlifting lever 25 are pushed up to the feeding position against theurging force of the pressurizing spring 39.

Therefore, if the feed roller 211 is to be separated from the sheetmerely by the lifting operation of the feed roller 211, the minimumdrive amount for moving the feed roller 211 from the feeding position tothe upper position is not sufficient as the drive amount required fordriving the lift motor 35. When the lift motor 35 starts to rotate inthe reverse direction, the roller lifting link 37 moves upward in astate where the feed roller 211 stays at the feeding position (t).Thereafter, the lift motor 35 rotates further in the reverse directionwhile the roller lifting link 37 is in contact with the roller liftinglever 25, the roller lifting lever 25 pivots upward for the first timeand the feed roller 211 moves upward from the feeding position. Thereby,the drive amount of the lift motor 35 that is required additionallycorresponds to the lifting distance from the lower position to thefeeding position (t) of the feed roller 211, which is also the amount ofexcessive lowering of the feed roller 211 from the feeding position (t)to the lower position in other words.

A case has been illustrated where the feed roller 211 is separated fromthe sheet only by the lifting operation of the feed roller 211, but thesame applies to a case where the feed roller 211 is separated from thesheet only by the lowering operation of the lift plate 31 from thefeed-roller contact state. Even in this case, additional rotation of thelift motor 35 in the reverse direction becomes necessary, and the driveamount thereof corresponds to the excessive lowering of the feed roller211.

In contrast, according to the present embodiment, both the feed roller211 and the lift plate 31 are operated using the driving force of thelift motor 35 during the feed-roller separating operation. Therefore,the feed roller 211 can be separated from the sheet by a smaller driveamount of the lift motor 35 than the configuration where only either thefeed roller 211 or the lift plate 31 is moved to separate the feedroller 211 from the sheet. Thereby, the period of time during whichoperation noise is generated in the driving time of the lift motor 35can be shortened, and the life of the motor can be elongated by cuttingdown the drive amount of the lift motor 35.

In a configuration where the feed roller 211 is separated from the sheetby lifting and lowering only the lift plate 31, the pivoting amount ofthe lift plate 31 is to be ensured to separate the sheet from the feedroller 211 reliably even in a state where the lift plate 31 is fullyloaded with sheets. Therefore, it is necessary to increase the size ofthe cassette 3 to ensure the pivot space of the lift plate 31, or to seta smaller amount as the amount of a full load. In contrast, according tothe present embodiment, both the feed roller 211 and the lift plate 31are lifted and lowered during the feed-roller separating operation, sothat the apparatus can be downsized while maintaining the amount of afull load.

The length of the excessive lowering according to the above-describedexample is set so as to compress the pressurizing spring 39 and ensurethe pressurizing force of the feed roller 211. However, the presenttechnique is also applicable to a case where the feeding position is setto a higher position than the lower position so that the feed roller 211contacts the sheet reliably in a configuration where the pressurizingforce of the feed roller 211 is ensured by using the own weight of thefeed roller unit 21.

Control Method

The control method of the sheet feeder 2 according to the presentembodiment will be described with reference to FIGS. 8 and 9 . FIG. 8 isa block diagram illustrating a control configuration of the imageforming apparatus 1 related to the sheet feeder 2, and FIG. 9 is aflowchart illustrating an example of the control method of the sheetfeeder 2.

As illustrated in FIG. 8 , the control unit 70 serving as a controlleris provided on the image forming apparatus 1. The control unit 70 is acontrol circuit including a central processing unit (CPU 71) serving asan execution unit of programs, a read only memory (ROM 72) serving as astorage unit and a rewritable random access memory (RAM 73). The CPU 71controls various units of the image forming apparatus 1 including thesheet feeder 2 by reading and executing programs stored in the ROM 72.The ROM 72 stores programs and various setting data required forcontrolling the image forming apparatus 1, and the RAM 73 serves as aworkspace for the CPU 71 executing programs. The ROM 72 and the RAM 73are examples of a non-transitory storage medium storing control programsfor controlling the image forming apparatus 1 according to a specificmethod.

The CPU 71 operates the sheet feeder 2 by activating the lift motor 35,a sheet feed motor 40 and an electromagnetic clutch 41 while recognizingthe current status of the sheet feeder 2 based on the feed positionsensor 215 and the cassette open/close sensor 74. The electromagneticclutch 41 is a clutch that is provided between the sheet feed motor 40and the feed roller 211 and the conveyance roller 212 that constitutethe feed roller unit 21. The electromagnetic clutch 41 couples andcancels, i.e., engages and disengages the drive transmission to the feedroller 211 and the conveyance roller 212 based on ON/OFF of powersupply.

The sheet feed motor 40 according to the present embodiment also servesas a driving source of the conveyance roller pair 4 (refer to FIG. 1 )that serves as a conveyance member to convey the sheet at a positiondownstream of the feed roller unit 21. Therefore, the CPU 71 is capableof controlling the feeding of a succeeding sheet using the feed rollerunit 21 while continuing conveyance operation of a preceding sheet usingthe conveyance roller pair 4 by controlling ON and OFF of power to theelectromagnetic clutch 41 in a state where the sheet feed motor 40 isrotating.

Now, a control method of the sheet feeder 2 will be described withreference to a flowchart of FIG. 9 . Various steps of the presentflowchart will be carried out by the CPU 71 of the control unit 70executing programs. In the following description, whether the conveyancetarget sheet has passed a predetermined position on the conveyance pathis determined based on the result of detection of a sheet by a sensorarranged on the conveyance path or based on the rotation amount of thesheet feed motor 40 from the time these sensors have detected the sheet.

Processing of the flowchart is started in a standby state in which theimage forming apparatus 1 is standing by for entry of a print job. In acase where the print job is entered by having image data transmittedfrom an external computer to the image forming apparatus 1 (S1: Yes),the CPU 71 starts the feed-roller contact operation by rotating a liftmotor S2 in a normal direction (S2). By the lift motor 35 rotating inthe normal direction, the feed roller 211 starts to be lowered from theupper position and the lift plate 31 starts to be lifted from a standbyposition. The standby position refers to a position where the lift plate31 has been lowered by the feed-roller separating operation when aprevious job has ended. In S2, after the lift motor 35 has started torotate in the normal direction, the feed roller 211 passes the feedingposition temporarily before reaching the lower position, and the feedposition sensor 215 detects the detection portion 213 a, but at thatpoint of time, the feed-roller contact operation has not been completed.Therefore, the CPU 71 stands by for a predetermined time from the startof rotation of the lift motor 35 in the normal direction, and therotation of the lift motor 35 in the normal direction is continuedregardless of the detection result of the feed position sensor 215 (S3).

After the feed roller 211 reaches the lower position, the upper surfaceof the sheet supported on the lift plate 31 being lifted comes intocontact with the feed roller 211 and the feed roller unit 21 is liftedup against the urging force of the pressurizing spring 39. Then, whenthe detection portion 213 a is detected again by the feed positionsensor 215 (S4: Yes), the CPU 71 determines that the feed-roller contactoperation has been completed and stops the lift motor 35 (S5). Thereby,the sheet feeder 2 becomes the feed-roller contact state. The processesof S1 to S5 described above will also be executed in a case where theCPU 71 detects via the cassette open/close sensor 74 that the cassette 3in an opened state has been closed.

Now, the contents of control of the sheet feed motor 40 and control ofthe lift motor 35 being executed in parallel will be described.

Control of Sheet Feed Motor

In a case where a preparation operation in the image forming unit 5 iscompleted, a feed start command is generated and the sheet feed motor 40is started (S6). After the sheet feed motor 40 has been started, poweris supplied to the electromagnetic clutch 41 and the clutch 41 isengaged, by which the driving force of the sheet feed motor 40 istransmitted to the feed roller 211 and the conveyance roller 212 (S7).By the feed roller 211 rotating in the feed-roller contact state, theuppermost sheet on the lift plate 31 is sent out from the cassette 3 andsheets are fed one at a time in a separated state by the conveyanceroller 212 and the separation roller 24.

Before a trailing edge, that is upstream end in the feeding direction,of the sheet being fed passes a contact position with the feed roller211, power to the electromagnetic clutch 41 is shut off and the clutch41 will be in a disengaged state (S8). Thereby, the drive of the feedroller unit 21 is stopped, so that the occurrence of a conveyancefailure in which the feed roller 211 feeds a succeeding sheet of thesheet being conveyed to cause multiple feeding can be prevented.Further, at the point of time of disengagement of the electromagneticclutch 41, the leading edge, that is, downstream end in the feedingdirection, of the sheet has already reached the conveyance roller pair 4positioned downstream, so that conveyance is continued by the conveyanceroller pair 4 even after disengagement. The sheet being conveyed by theconveyance roller pair 4 passes through the transfer portion and thefixing unit, by which an image is formed to the sheet, before the sheetis discharged by the sheet discharge roller pair.

If the number of printed sheets has not yet reached the number of sheetsdesignated in the print job (S9: Yes), processes of S7 and S8 arerepeatedly executed to perform image forming to succeeding sheets. Inthis case, engaging timing of the electromagnetic clutch 41 iscontrolled so that the leading edge of the succeeding sheet follows thetrailing edge of the preceding sheet at a fixed distance, so-calledsheet-to-sheet interval. As described, according to the presentembodiment, the electromagnetic clutch 41 is turned on and offrepeatedly in a state where the feed-roller contact state is maintainedto feed the sheets one at a time. The present configuration is effectivein setting a short sheet-to-sheet interval and improving productivity ofthe image forming apparatus compared to a configuration where the feedroller 211 is lifted and lowered by a cam structure each time a sheet isfed, or compared to a configuration where the sheet feed motor 40 isturned on and off each time a sheet is fed. This is because the responsetime of the electromagnetic clutch is normally shorter than the timerequired to lift and lower the feed roller 211 mechanically or the timerequired to start and stop the sheet feed motor 40.

If the number of printed sheets has become equal to the number of sheetsdesignated by the print job (S9: No), a process to stop the sheet feedmotor 40 is performed. In this case, the driving of the sheet feed motor40 is continued until the trailing edge of the final sheet has passedthrough the conveyance roller pair 4, and after the sheet has passedthrough the conveyance roller pair 4, the sheet feed motor 40 is stopped(S10).

Control of Lift Motor

Meanwhile, during feeding of sheets, the CPU 71 maintains thefeed-roller contact state, and after the leading edge of the final sheethas reached the conveyance roller pair 4 (S11: Yes), the CPU 71 rotatesthe lift motor 35 in the reverse direction and starts the feed-rollerseparating operation (S12). The lift motor 35 is stopped after apredetermined time has elapsed from starting of the rotation in thereverse direction (S13). The predetermined time refers to a time formoving the feed roller 211 to the upper position and moving the liftplate 31 to a position, i.e., standby position, so that the uppermostsheet is positioned lower than the lower position of the feed roller211. Therefore, the above-described feed-roller contact operation (S2 toS5) is ready for re-execution by rotating the lift motor 35 in thenormal direction at a point of time where the lift motor 35 stops aftera predetermined time has elapsed. By the lift motor 35 being stopped andthe sheet feed motor being stopped at S10, the sheet feeder 2 returns toa standby state where a succeeding job entry can be received.

In a case where the print job requires images to be formed to aplurality of sheets, during a period of time where feeding of sheets iscontinuously executed (S11: No), the CPU 71 performs control to maintainthe height of the uppermost sheet on the lift motor 35 to the feedingposition. That is, when the number of sheets on the lift plate 31 isreduced by feeding sheets and the detection signal of the feed positionsensor 215 has turned from on to off, an operation is repeatedlyperformed to rotate the lift motor 35 for a predetermined amount in thenormal direction to lift the lift plate 31 up. Thereby, even if theremaining amount of sheets is reduced, the height of the uppermost sheetis maintained at the feeding position, and pressurizing force of thefeed roller 211 to the sheet is maintained within an appropriate range.

Now, according to the present embodiment, the control of the lift motor35, that is, control of the contact and separation of the feed roller,which serves as a driving source for lifting and lowering the feedroller 211 and lifting and lowering the lift plate 31, is performedindependently from the control, i.e., conveyance control, of the sheetfeed motor 40 serving as a driving source for feeding sheets. Therefore,in a state where the sheet feed motor 40 is still rotating forconveyance of the final sheet as a process for completing the print job,the lift motor 35 can rotate in the reverse direction to start theoperation of separating the feed roller 211 from the sheet. In otherwords, it is possible to start the feed-roller separating operationduring execution of conveyance control of the sheet.

Specifically, at a point of time where the leading edge of the finalsheet has reached the conveyance roller pair 4 (S11: Yes), the trailingedge of the final sheet is still positioned upstream of the conveyanceroller pair 4, so that the driving of the conveyance roller pair 4 bythe sheet feed motor 40 is continued. In the present embodiment, thelift motor 35 rotates in the reverse direction in this state to startthe feed-roller separating operation. At this time, because the finalsheet is already nipped by the conveyance roller pair 4, the conveyanceof the final sheet is continued reliably even if the feed roller 211 isseparated from the final sheet by the lift motor 35 rotating in thereverse direction.

Thereby, at least a portion of a period of execution of the feed-rollerseparating operation overlaps with a period during which the final sheetis conveyed by the conveyance roller pair 4 and conveyance mechanismsarranged downstream thereof, such as the transfer portion, the fixingunit and the sheet discharge roller pair. That is, at least a portion ofthe period during which driving noise of the lift motor 35 is generatedfor separating the feed roller 211 from the sheet falls within theperiod during which operation noise of conveying the sheet in the imageforming apparatus is generated, so that the period during which theimage forming apparatus generates noise can be shortened.

Further, if the contents of jobs are the same, the required time fromthe entry of a job to the returning of the sheet feeder 2 to the standbystate is shortened compared to a configuration where the feed roller 211is lifted to the upper position by rotating the sheet feed motor 40 inthe reverse direction after the final sheet has been fed. In addition,according to the present embodiment, since the present embodiment doesnot adopt a configuration to lift and lower the feed roller 211 byrotating the sheet feed motor 40 in the reverse direction, drive of thesheet feed motor 40 rotating in the reverse direction can be used forother control purposes.

Modified Example

According further to the present embodiment, a configuration is adoptedwhere the feed roller unit 21 is detachably attached to the feedingframe 22, but a configuration can also be adopted where the feed rollerunit 21 is not attached in a detachable manner. For example, aconfiguration can be adopted where the roller holder 213 is formedintegrally with the roller lifting lever 25, in which the feed roller211 and the conveyance roller 212 can be independently detachablyattached to the integrated structure.

Second Embodiment

Next, a second embodiment will be described with reference to FIGS. 10to 12 . According to the present embodiment, a configuration of theroller lifting portion 30B differs from the first embodiment. Elementshaving substantially the same configurations and functions as the firstembodiment are denoted with the same reference numbers as in the firstembodiment, and descriptions thereof are omitted.

FIG. 10 is a perspective view illustrating a configuration of the rollerlifting portion 30B according to the present embodiment. Similar to thefirst embodiment, the roller lifting portion 30B is a device, serving asa feed roller contact-separation portion, that moves the feed roller 211to be in contact with and separated from the sheet by swinging theroller holder 213 using the driving force of the lift motor 35.

The roller lifting portion 30B according to the present embodimentadopts a configuration that includes a roller-coupled lever 26 and alink-coupled lever 27 instead of the roller lifting lever 25 accordingto the first embodiment. That is, the roller lifting portion 30B iscomposed of the roller lifting gear 36, the roller lifting link 37, theroller-coupled lever 26 and the link-coupled lever 27. The configurationof the roller lifting gear 36 and the roller lifting link 37 is similarto the first embodiment, wherein the roller lifting link 37 is moved bysliding motion upward and downward by the driving force beingtransmitted via the roller lifting gear 36 when the lift motor 35rotates in the normal and reverse directions.

However, unlike the first embodiment, the roller lifting link 37 isdesigned to slide upward when the lift motor 35 rotates in the normaldirection and to slide downward when the lift motor 35 rotates in thereverse direction. Such configuration can be realized, for example, byproviding an idler gear between the roller lifting gear 36 according tothe present embodiment and a gear of the reduction gear train 38 that ismeshed with the roller lifting gear 36 according to the firstembodiment.

The roller-coupled lever 26 and the link-coupled lever 27 are bothsupported swingably with respect to the feeding frame 22 and mutuallyconnected to swing in linkage with each other. In the presentembodiment, the roller-coupled lever 26 and the link-coupled lever 27swing about a swing axis X2 serving as a common axis. The swing axis X2is an axis parallel to the feeding direction Fd viewed in the verticaldirection, i.e., axis perpendicular to the rotational axis direction ofthe feed roller 211. The roller-coupled lever 26 has an end portion 26 aengaged with the roller holder 213 of the feed roller unit 21, and theroller-coupled lever 26 swings in linkage with the feed roller unit 21.The link-coupled lever 27 has an end portion 27 a opposed to the rollerlifting link 37, and the link-coupled lever 27 swings in linkage withthe roller lifting link 37. Further, the roller-coupled lever 26 and thelink-coupled lever 27 can be configured as an integrated member by beingmutually fixed to each other, or can be configured so that the leversare coupled to enable relative movement via a spring member.

The feed roller unit 21 can be attached detachably to the feeding frame22, and an engagement portion, i.e., connecting portion, of the feedroller unit 21 and the roller-coupled lever 26 can also be attacheddetachably. Of course, the engagement portion is configured so that theend portion 26 a of the roller-coupled lever 26 fits to the hook portion213 b provided on the roller holder 213.

The feed roller unit 21 is removable from the feeding frame 22 toward adirection R intersecting a rotational axis of the feed roller 211. Incorrespondence therewith, the hook portion 213 b is formed to have arecessed shape where an upstream side in a removal direction R isopened, and along with the operation to remove the feed roller unit 21,the end portion 26 a of the roller-coupled lever 26 is disengaged fromthe hook portion 213 b. In a case where the feed roller unit 21 isattached to the feeding frame 22 toward a direction opposite to theremoval direction R, the end portion 26 a of the roller-coupled lever 26is fit to the hook portion 213 b, and the roller-coupled lever 26 andthe roller holder 213 are in a state swingable in linkage with eachother.

Next, the lifting and lowering operation of the lift plate 31 and thefeed roller 211 by the lifting mechanism 30 according to the presentembodiment will be described with reference to FIGS. 11A to 12B. FIG.11A is a schematic drawing illustrating a feed-roller contact stateviewed in a rotational axis direction of the feed roller 211, that is, awidth direction of the sheet. FIG. 11B is a schematic drawingillustrating a feed-roller separated state viewed in the rotational axisdirection of the feed roller 211. FIG. 12A is a schematic drawingillustrating a feed-roller contact state viewed from the downstream sideof the feeding direction, and FIG. 12B is a schematic drawingillustrating a feed-roller separated state viewed from the downstreamside of the feeding direction.

As illustrated in FIGS. 11A and 12A, the lift motor 35 rotates in thenormal direction in the feed-roller contact operation. Thereby, thelifting mechanism 30 performs operation to lower the feed roller 211 bythe roller lifting portion 30B and lift the lift plate 31 by the liftplate lifting portion 30A. That is, the roller lifting link 37 lifts byrotation of the lift motor 35 in the normal direction (arrow A2), andalong therewith, the roller-coupled lever 26 and the link-coupled lever27 swing in a first swinging direction (arrow E1). Further, the feedroller unit 21 pivots downward in linkage with the roller-coupled lever26 (arrow C1). In parallel therewith, the lift member 32 pivots upwardby the rotation of the lift motor 35 in the normal direction and liftsthe lift plate 31 up (arrow D1). As described earlier, the lifting ofthe lift plate 31 is stopped by the feed position sensor 215 detectingthe detection portion 213 a of the roller holder 213, and thefeed-roller contact state is realized.

Meanwhile, as illustrated in FIGS. 11B and 12B, the lift motor 35rotates in the reverse direction during the feed-roller separatingoperation. Thereby, the lifting mechanism 30 performs an operation tolift the feed roller 211 by the roller lifting portion 30B and lower thelift plate 31 by the lift plate lifting portion 30A. That is, the rollerlifting link 37 lowers by rotation of the lift motor 35 in the reversedirection (arrow A1), and along therewith, the roller-coupled lever 26and the link-coupled lever 27 swing in a second swinging direction(arrow E2). The feed roller unit 21 pivots upward in linkage with theroller-coupled lever 26 (arrow C2). In parallel therewith, the liftmember 32 pivots downward by rotation of the lift motor 35 in thereverse direction, lowering the lift plate 31 (arrow D2). Thereby, thefeed-roller separated state is realized.

As described, according to the present embodiment, even though a portionof the configuration of the roller lifting portion 30B differs from thefirst embodiment, the driving force of the lift motor 35 is used duringthe feed-roller separating operation to operate both the feed roller 211and the lift plate 31, similar to the first embodiment. Therefore,similar to the first embodiment, the feed-roller separating operation isperformed speedily to shorten the period of time during which operationnoise is generated in the driving time of the lift motor 35 and cut downthe drive amount of the lift motor 35 to thereby elongate the life ofthe motor. Since the feed-roller separating operation is performed bylifting and lowering both the feed roller 211 and the lift plate 31, theapparatus can be downsized while maintaining the same amount of fullload.

Further, the operation of the sheet feeder 2 according to the presentembodiment is controlled by a control method similar to the onedescribed in the first embodiment. Therefore, similar to the firstembodiment, it may be possible to shorten the period of time duringwhich the image forming apparatus generates noise. Further, the timerequired from the entry of a job to the returning of the sheet feeder 2to the standby state is shortened, and an advantage is realized in thatthe rotation of the sheet feed motor 40 in the reverse direction can beused for other control purposes.

Even further, similar to the first embodiment, the feed roller unit 21according to the present embodiment may adopt a configuration where itis not detachably attached to the feeding frame 22.

Other Embodiments

The first and second embodiments described above have been describedbased on the sheet feeder 2 serving as a sheet feeding apparatusassembled to the image forming apparatus. However, the present techniqueis not limited to such example, and it can also be applied to a sheetfeeding apparatus that is disposed independently from the image formingapparatus. For example, the present technique is adoptable to a sheetfeeding apparatus that is coupled to an image forming apparatus toconstitute an image forming system together with the image formingapparatus, that feeds sheets serving as recording material to the imageforming apparatus.

Embodiment(s) of the present invention can also be realized by acomputer of a system or apparatus that reads out and executes computerexecutable instructions (e.g., one or more programs) recorded on astorage medium (which may also be referred to more fully as a‘non-transitory computer-readable storage medium’) to perform thefunctions of one or more of the above-described embodiment(s) and/orthat includes one or more circuits (e.g., application specificintegrated circuit (ASIC)) for performing the functions of one or moreof the above-described embodiment(s), and by a method performed by thecomputer of the system or apparatus by, for example, reading out andexecuting the computer executable instructions from the storage mediumto perform the functions of one or more of the above-describedembodiment(s) and/or controlling the one or more circuits to perform thefunctions of one or more of the above-described embodiment(s). Thecomputer may comprise one or more processors (e.g., central processingunit (CPU), micro processing unit (MPU)) and may include a network ofseparate computers or separate processors to read out and execute thecomputer executable instructions. The computer executable instructionsmay be provided to the computer, for example, from a network or thestorage medium. The storage medium may include, for example, one or moreof a hard disk, a random-access memory (RAM), a read only memory (ROM),a storage of distributed computing systems, an optical disk (such as acompact disc (CD), digital versatile disc (DVD), or Blu-ray Disc (BD)™),a flash memory device, a memory card, and the like.

While the present invention has been described with reference toexemplary embodiments, it is to be understood that the invention is notlimited to the disclosed exemplary embodiments. The scope of thefollowing claims is to be accorded the broadest interpretation so as toencompass all such modifications and equivalent structures andfunctions.

This application claims the benefit of Japanese Patent Application No.2019-154160, filed on Aug. 26, 2019, which is hereby incorporated byreference herein in its entirety.

1. A sheet feeding apparatus comprising: a sheet supporting portionconfigured to support a sheet; a feeding member configured to contact anupper surface of the sheet supported on the sheet supporting portion andfeed the sheet; a drive motor configured to rotate in a first directionand in a second direction opposite to the first direction; and a liftingmechanism connected to the drive motor and configured to lift the sheetsupporting portion and lower the feeding member in a case where thedrive motor rotates in the first direction, and to lower the sheetsupporting portion and lift the feeding member in a case where the drivemotor rotates in the second direction. 2.-12. (canceled)